The effects of high urinary potassium concentration on pelvic nerve mechanoreceptors and 'silent' afferents from the rat bladder

Bladder infection with uropathogenic Escherichia coli increases the excitability of afferent neurons

Urinary tract infections (UTIs) cause bladder hyperactivity and pelvic pain, but the underlying causes of these symptoms remain unknown. We investigated whether afferent sensitization contributes to the bladder overactivity and pain observed in mice suffering from experimentally induced bacterial cystitis. Inoculation of mouse bladders with the uropathogenic Escherichia coli strain UTI89 caused pelvic allodynia, increased voiding frequency, and prompted an acute inflammatory process marked by leukocytic infiltration and edema of the mucosa. Compared with controls, isolated bladder sensory neurons from UTI-treated mice exhibited a depolarized resting membrane potential, lower action potential threshold and rheobase, and increased firing in response to suprathreshold stimulation. To determine whether bacterial virulence factors can contribute to the sensitization of bladder afferents, neurons isolated from naïve mice were incubated with supernatants collected from bacterial cultures with or depleted of lipopolysaccharide (LPS). Supernatants containing LPS prompted the sensitization of bladder sensory neurons with both tetrodotoxin (TTX)-resistant and TTX-sensitive action potentials. However, bladder sensory neurons with TTX-sensitive action potentials were not affected by bacterial supernatants depleted of LPS. Unexpectedly, ultrapure LPS increased the excitability only of bladder sensory neurons with TTX-resistant action potentials, but the supplementation of supernatants depleted of LPS with ultrapure LPS resulted in the sensitization of both population of bladder sensory neurons. In summary, the results of our study indicate that multiple virulence factors released from UTI89 act on bladder sensory neurons to prompt their sensitization. These sensitized bladder sensory neurons mediate, at least in part, the bladder hyperactivity and pelvic pain seen in mice inoculated with UTI89.NEW & NOTEWORTHY Urinary tract infection (UTI) produced by uropathogenic Escherichia coli (UPEC) promotes sensitization of bladder afferent sensory neurons with tetrodotoxin-resistant and tetrodotoxin-sensitive action potentials. Lipopolysaccharide and other virulence factors produced by UPEC contribute to the sensitization of bladder afferents in UTI. In conclusion, sensitized afferents contribute to the voiding symptoms and pelvic pain present in mice bladder inoculated with UPEC.

Acid-sensing ion channels modulate bladder nociception

Sensitization of neuronal pathways and persistent afferent drive are major contributors to somatic and visceral pain. However, the underlying mechanisms that govern whether afferent signaling will give rise to sensitization and pain are not fully understood. In the present report, we investigated the contribution of acid-sensing ion channels (ASICs) to bladder nociception in a model of chemical cystitis induced by cyclophosphamide (CYP). We found that the administration of CYP to mice lacking ASIC3, a subunit primarily expressed in sensory neurons, generates pelvic allodynia at a time point at which only modest changes in pelvic sensitivity are apparent in wild-type mice. The differences in mechanical pelvic sensitivity between wild-type and Asic3 knockout mice treated with CYP were ascribed to sensitized bladder C nociceptors. Deletion of Asic3 from bladder sensory neurons abolished their ability to discharge action potentials in response to extracellular acidification. Collectively, the results of our study support the notion that protons and their cognate ASIC receptors are part of a mechanism that operates at the nerve terminals to control nociceptor excitability and sensitization.NEW & NOTEWORTHY Our study indicates that protons and their cognate acid-sensing ion channel receptors are part of a mechanism that operates at bladder afferent terminals to control their function and that the loss of this regulatory mechanism results in hyperactivation of nociceptive pathways and the development of pain in the setting of chemical-induced cystitis.

The Urothelium: Life in a Liquid Environment

The urothelium, which lines the renal pelvis, ureters, urinary bladder, and proximal urethra, forms a high-resistance but adaptable barrier that surveils its mechanochemical environment and communicates changes to underlying tissues including afferent nerve fibers and the smooth muscle. The goal of this review is to summarize new insights into urothelial biology and function that have occurred in the past decade. After familiarizing the reader with key aspects of urothelial histology, we describe new insights into urothelial development and regeneration. This is followed by an extended discussion of urothelial barrier function, including information about the roles of the glycocalyx, ion and water transport, tight junctions, and the cellular and tissue shape changes and other adaptations that accompany expansion and contraction of the lower urinary tract. We also explore evidence that the urothelium can alter the water and solute composition of urine during normal physiology and in response to overdistension. We complete the review by providing an overview of our current knowledge about the urothelial environment, discussing the sensor and transducer functions of the urothelium, exploring the role of circadian rhythms in urothelial gene expression, and describing novel research tools that are likely to further advance our understanding of urothelial biology.

ASIC3 fine-tunes bladder sensory signaling

Acid-sensing ion channels (ASICs) are trimeric proton-activated, cation-selective neuronal channels that are considered to play important roles in mechanosensation and nociception. Here we investigated the role of ASIC3, a subunit primarily expressed in sensory neurons, in bladder sensory signaling and function. We found that extracellular acidification evokes a transient increase in current, consistent with the kinetics of activation and desensitization of ASICs, in ~25% of the bladder sensory neurons harvested from both wild-type (WT) and ASIC3 knockout (KO) mice. The absence of ASIC3 increased the magnitude of the peak evoked by extracellular acidification and reduced the rate of decay of the ASIC-like currents. These findings suggest that ASICs are assembled as heteromers and that the absence of ASIC3 alters the composition of these channels in bladder sensory neurons. Consistent with the notion that ASIC3 serves as a proton sensor, 59% of the bladder sensory neurons harvested from WT, but none from ASIC3 KO mice, fired action potentials in response to extracellular acidification. Studies of bladder function revealed that ASIC3 deletion reduces voiding volume and the pressure required to trigger micturition. In summary, our findings indicate that ASIC3 plays a role in the control of bladder function by modulating the response of afferents to filling.

Urothelial Tight Junction Barrier Dysfunction Sensitizes Bladder Afferents

Interstitial cystitis/bladder pain syndrome (IC/BPS) is a chronic voiding disorder that presents with pain in the urinary bladder and surrounding pelvic region. A growing body of evidence suggests that an increase in the permeability of the urothelium, the epithelial barrier that lines the interior of the bladder, contributes to the symptoms of IC/BPS. To examine the consequence of increased urothelial permeability on pelvic pain and afferent excitability, we overexpressed in the urothelium claudin 2 (Cldn2), a tight junction (TJ)-associated protein whose message is significantly upregulated in biopsies of IC/BPS patients. Consistent with the presence of bladder-derived pain, rats overexpressing Cldn2 showed hypersensitivity to von Frey filaments applied to the pelvic region. Overexpression of Cldn2 increased the expression of c-Fos and promoted the activation of ERK1/2 in spinal cord segments receiving bladder input, which we conceive is the result of noxious stimulation of afferent pathways. To determine whether the mechanical allodynia observed in rats with reduced urothelial barrier function results from altered afferent activity, we examined the firing of acutely isolated bladder sensory neurons. In patch-clamp recordings, about 30% of the bladder sensory neurons from rats transduced with Cldn2, but not controls transduced with GFP, displayed spontaneous activity. Furthermore, bladder sensory neurons with tetrodotoxin-sensitive (TTX-S) action potentials from rats transduced with Cldn2 showed hyperexcitability in response to suprathreshold electrical stimulation. These findings suggest that as a result of a leaky urothelium, the diffusion of urinary solutes through the urothelial barrier sensitizes bladders afferents, promoting voiding at low filling volumes and pain.

Electrophysiological properties of lumbosacral primary afferent neurons innervating urothelial and non-urothelial layers of mouse urinary bladder

Pelvic nerve (PN) bladder primary afferent neurons were retrogradely labeled by intraparenchymal (IPar) microinjection of fluorescent tracer or intravesical (IVes) infusion of tracer into the bladder lumen. IPar and IVes techniques labeled two distinct populations of PN bladder neurons differentiated on the basis of dorsal root ganglion (DRG) soma labeling, dye distribution within the bladder, and intrinsic electrophysiological properties. IPar (Fast blue)- and IVes (DiI)-labeled neurons accounted for 91.5% (378.3±32.3) and 8% (33.0±26.0) of all labeled neurons, respectively (p<0.01), with only 2.0±1.2 neurons labeled by both techniques. When dyes were switched, IPar (DiI)- and IVes (Fast blue) labeled neurons accounted for 77.6% (103.0±25.8) and 22.4% (29.8±10.5), respectively (P<0.05), with 6.0±1.5 double-labeled neurons. Following IPar labeling, DiI was distributed throughout non-urothelial layers of the bladder. In contrast, dye was contained within the urothelium and occasionally the submucosa after IVes labeling. Electrophysiological properties of DiI-labeled IPar and IVes DRG neurons were characterized by whole-mount, in situ patch-clamp recordings. IPar- and IVes-labeled neurons differed significantly with respect to rheobase, input resistance, membrane capacitance, amplitude of inactivating and sustained K(+) currents, and rebound action potential firing, suggesting that the IVes population is more excitable. This study is the first to demonstrate that IVes labeling is a minimally invasive approach for retrograde labeling of PN bladder afferent neurons, to selectively identify urothelial versus non-urothelial bladder DRG neurons, and to elucidate electrophysiological properties of urothelial and non-urothelial afferents in an intact DRG soma preparation.

Properties of the major classes of mechanoreceptors in the guinea pig bladder

Sensory neurons represent an attractive target for pharmacological treatment of various bladder disorders. However the properties of major classes of mechano-sensory neurons projecting to the bladder have not been systematically established. An in vitro bladder preparation was used to examine the effects of a range of mechanical stimuli (stretch, von Frey hair stroking and focal compression of receptive fields) and chemical stimuli (1 mm alpha,beta-methylene ATP, hypertonic solutions (500 mm NaCl) and 3 microm capsaicin) during electrophysiological recordings from guinea pig bladder afferents. Four functionally distinct populations of bladder sensory neurons were distinguished by these stimuli. The first class, muscle mechanoreceptors, were activated by stretch but not by mucosal stroking with light (0.05-0.1 mN) von Frey hairs or by hypertonic saline, alpha,beta-methylene ATP or capsaicin. Removal of the urothelium did not affect their stretch-induced firing. The second class, muscle-mucosal mechanoreceptors, were activated by both stretch and mucosal stroking with light von Frey hairs or by hypertonic saline and by alpha,beta-methylene ATP, but not by capsaicin. Removal of the urothelium reduced their stretch- and stroking-induced firing. The third class, mucosal high-responding mechanoreceptors, were stretch-insensitive but could be activated by mucosal stroking with light von Frey hairs or by hypertonic saline, alpha,beta-methylene ATP and capsaicin. Stroking-induced firing was significantly reduced by removal of the urothelium. The fourth class, mucosal low-responding mechanoreceptors, were stretch insensitive but could be weakly activated by mucosal stroking with light von Frey hairs but not by hypertonic saline, alpha,beta-methylene ATP or capsaicin. Removal of the urothelium reduced mucosal stroking-induced firing. All four populations of afferents conducted in the C-fibre range and showed class-dependent differences in spike amplitude and duration. At least four functional classes of bladder mechanoreceptors can be readily distinguished by different mechanisms of activation and are likely to transmit different types of information to the central nervous system.

Control of bladder function by peripheral nerves: avenues for novel drug targets

The micturition reflex involves afferent nerve activation when the bladder is sufficiently full and subsequent controlled firing of parasympathetic efferent nerves to contract the detrusor muscle as part of the voiding mechanism. Alteration of the sensitivity of afferent activation or loss of control over transmitter release could lead to sensory- or motor-activated incontinence, respectively. The control mechanisms that regulate these 2 activities remain poorly understood. Current opinion is that the sensation of bladder fullness is relayed by afferent nerves in the mucosal layer, which are activated by the release of chemical mediators, such as adenosine triphosphate (ATP), from the urothelium when it is stretched as the bladder fills. This hypothesis supports the concept that other chemical signals that affect bladder sensation (eg, changes in urine composition and agents such as capsaicin) can modulate the sensitivity of the basic system. It has also been proposed that a layer of myofibroblasts immediately below the basal lamina of the urothelium acts as a variable gain regulator of the sensory process between ATP release and afferent excitation. These myofibroblasts are functionally connected to form an electrical syncytium, make close contact with nerves, and respond by generating electrical responses and transient increases in intracellular Ca2+ when exposed to ATP. On the efferent side, using a guinea pig detrusor model, possible modulators of transmitter release have been investigated, including adenosine (the breakdown product of the neurotransmitter ATP). Adenosine reduces the force of nerve-mediated contractions by acting predominantly at presynaptic sites at the nerve-muscle junction via a subtype of an adenosine receptor-the A1 receptor. An additional effect, possibly via A2 receptors, is also present on the detrusor muscle itself. These actions of adenosine are less evident in human detrusor muscle but remain a potential modulatory target. In summary, the cellular and molecular regulation of bladder fullness sensation and efferent transmitter release are becoming better understood and represent potential drug targets for the management of detrusor overactivity.

Threshold for efferent bladder nerve firing in the rat

In this study, the mechanism involved in the initiation of voiding was investigated. Bladder pressure and bladder and urethral nerve activity were recorded in the anesthetized rat. Bladder nerve activity was resolved into afferent and efferent activity by means of a theoretical model. The beginning of an active bladder contraction was defined as the onset of bladder efferent firing at a certain time (t0). From t0 onward, bladder efferent activity increased linearly during deltat seconds (rise time) to a maximum. The pressure at t0 was 1.0 +/- 0.4 kPa, the afferent nerve activity at t0 was 2.0 +/- 0.6 microV (53 +/- 15% of maximum total nerve activity), and deltat was 11 +/- 13 s. Between contractions the afferent activity at t0 was never exceeded. Urethral afferent nerve activity started at bladder pressures of 2.1 +/- 1.1 kPa. Therefore, we concluded that urethral afferent nerve activity does not play a role in the initiation of bladder contractions; voiding contractions presumably are initiated by bladder afferent nerve activity exceeding a certain threshold.